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| United States Patent |
5,689,701
|
|
Ault
, et al.
|
November 18, 1997
|
System and method for providing compatibility between distributed file
system namespaces and operating system pathname syntax
Abstract
A system and method facilitating an operating system user's ability to
reference objects in a distributed file system having an incompatible
namespace. Compatibility is thereby provided between DFS namespaces and
operating system pathname syntax not supported in the DFS. A DFS pathname
prefix is associated with each drive letter that is attached to a DFS IFS
driver. Before an IFS driver is used, an application program issues a
command to associate a drive letter with a particular IFS driver. The
command issued also carries a DFS pathname prefix within a data buffer.
The IFS services the command by validating existence of the DFS pathname
prefix, and thereafter stores such prefix into an internal table of the
buffer where it is associated with the attached drive letter. File system
requests later received by the DFS client IFS driver carrying a pathname
containing that drive letter will have their file specifications edited by
the DFS code prior to processing. The drive letter in the pathname is
replaced by the DFS pathname prefix from the IFS driver's internal table,
and operating system slashes in operating system pathname are converted to
DFS slashes. The operating system user may thereby reference DFS objects
relative to a point in the DFS namespace using the operating system's
pathname syntax which the user is more comfortable with.
| Inventors:
|
Ault; Michael Bradford (Austin, TX);
Plassmann; Ernst Robert (Pflugerville, TX);
Rich; Bruce Arland (Round Rock, TX);
Wilkes; Michael David (Austin, TX)
|
| Assignee:
|
International Business Machines Corporation (Armonk, NY)
|
| Appl. No.:
|
572582 |
| Filed:
|
December 14, 1995 |
| Current U.S. Class: |
707/10; 707/1; 707/4; 707/9; 707/200; 707/205; 717/110; 717/120 |
| Intern'l Class: |
G06F 017/30; G06F 009/45 |
| Field of Search: |
395/600,575,200,700,500
364/200
|
References Cited
U.S. Patent Documents
| 4789986 | Dec., 1988 | Koizumi et al. | 371/36.
|
| 4825354 | Apr., 1989 | Agrawal etal. | 395/600.
|
| 4999766 | Mar., 1991 | Peters et al. | 364/200.
|
| 5218713 | Jun., 1993 | Hammer et al. | 395/800.
|
| 5317722 | May., 1994 | Evans | 395/500.
|
| 5329628 | Jul., 1994 | Yamamoto et al. | 395/425.
|
| 5339435 | Aug., 1994 | Lubkin et al. | 395/700.
|
| 5341499 | Aug., 1994 | Doragh | 395/650.
|
| 5349643 | Sep., 1994 | Cox et al. | 380/25.
|
| 5363487 | Nov., 1994 | Willman et al. | 395/700.
|
| 5377323 | Dec., 1994 | Vasudevan | 395/200.
|
| 5483652 | Jan., 1996 | Sudama et al. | 395/600.
|
| 5497463 | Mar., 1996 | Stein et al. | 395/200.
|
Primary Examiner: Black; Thomas G.
Assistant Examiner: Lewis; Cheryl R.
Attorney, Agent or Firm: Carwell; Robert M.
Parent Case Text
This is a continuation of application Ser. No. 08/355,873 filed Dec. 14,
1994, now abandoned.
CROSS-REFERENCE TO RELATED APPLICATIONS
The present application is related to copending U.S. patent application
Ser. No. 08/355,868, now U.S. Pat. No. 5,617,568 entitled "SYSTEM AND
METHOD FOR SUPPORTING FILE ATTRIBUTES ON A DISTRIBUTED FILE SYSTEM WITHOUT
NATIVE SUPPORT THEREFOR" filed on Dec. 14, 1994, and incorporated herein
by reference.
Claims
We claim:
1. A method implemented on a computer system including a computer executing
a first operating system, for referencing, with a computer executing a
second operating system, objects in a distributed file system (DFS) having
an incompatible namespace, said second operating system having at least
one drive and drive designator associated therewith and said DFS including
a DFS client installable file system (IFS) client driver, comprising:
generating a first request including a DFS pathname prefix with said second
operating system to associate said drive designator with said client
driver;
servicing said first request by validating existence of said prefix;
generating a second request having a file specification for said second
operating system including said drive designator in a pathname;
servicing said second request with said client drive by determining if said
second request carries said pathname containing a letter for said drive
designator;
editing said file specification with said DFS in response to said servicing
said second request by replacing said drive designator in said pathname
with said prefix;
generating, in response to said editing, a single universal distributed
file system namespace accessible by said first and second operating system
and having a syntax native to said second operating system; and
performing said referencing with said single universal distributed file
system namespace, said referencing being of said objects in said DFS on
said computer executing said first operating system.
2. A system implemented on a computer system including a computer executing
a first operating system, for referencing, with a computer executing a
second operating system, objects in a distributed file system (DFS) having
an incompatible namespace, said second operating system having at least
one drive and drive designator associated therewith and said DFS including
a DFS client installable file system (IFS) driver, comprising:
means for generating a first request including a DFS pathname prefix with
said second operating system to associate said drive designator with said
client driver;
means for servicing said first request by validating existence of said
prefix;
means for generating a second request having a file specification for said
second operating system including said drive designator in a pathname;
means for servicing said second request with said client driver by
determining if said second request carries said pathname containing a
letter for said drive designator;
means for editing said file specification with said DFS in response to said
second servicing said request by replacing said drive designator in said
pathname with said prefix;
means for generating, in response to said editing, a single universal
distributed file system name space accessible by said first and said
second operating system and having a syntax native to said second
operating system; and
performing said referencing with said single universal distributed file
system namespace, said referencing being of said objects in said DFS on
said computer executing said first operating system.
Description
TECHNICAL FIELD
This invention relates to operating systems and related file systems for
use in computer environments and, more particularly, to such systems in a
distributed file sytem environment.
BACKGROUND OF THE INVENTION
Most end-user applications consist of three basic components: a user
interface, a computational function, and information storage. In the early
evolution of computer systems, the general computing model for
non-distributed applications was most frequently employed wherein these
components were typically integrated in one system so as to be
indistinguishable.
As the art developed, it became evident that numerous benefits could be
obtained from distributed computing models wherein applications might be
distributed across computer systems, the simplest approach being to break
the application down into the hereinbefore noted components. It became
apparent that a user interface, for example, might be remote from the
computational function, and, in like manner, information storage might be
remote, as in a distributed file system, and that even the routines which
process the information in the files could be remote from the functions
which manage the physical storage media. It was further realized as the
art developed, that it may be desirable to even distribute portions of a
component itself among multiple machines, the foregoing being aspects of
what is known as distributed computing models.
Thus, high-powered individual computers and connectivity solutions (such as
LANS and WANS) are now dramatically changing the way computers process
information. The previously described isolated, dedicated, early
single-user systems are no longer the norm. Today, users expect to reach
beyond their desktop computers to exploit greater features, functionality,
and performance. Distributed computing solutions have existed since the
mid-1980's as, for example, in the Open Network Computing (ONC) and
Network Computing System (NCS) systems from Sun Microsystems and
Hewlett-Packard, respectively. Despite their availability distributed
applications were a relatively scarce commodity because of difficulty in
programming, with existing tools only being piecemeal solutions.
The distributed computing revolution challenged the computer industry to
provide interoperability among components in heterogeneous, networked
environments. Interoperability required more than mere connectivity a
network in order to allow applications to exploit the potential resources
in the networked environment and to provide dramatically improved
performance. Developers, in exploiting this environment, required a
complete set of tools within an architectural framework to ease
development. As a result, a distributed computing environment arose to
meet these needs in the form of a comprehensive integrated set of services
known as the Distributed Computing Environment (DCE) by the Open Systems
Foundation, which work across multiple systems remaining independent of
any single system.
Numerous characteristics serve to define the DCE model. Among these are
that DCE services are protected from a single point of failure by copying
the services and important files to additional hosts in the network.
Though many interdependencies exist among DCE components, the centralized
control allows management of each component independently from the others
whereby independently manageable sub-environments called cells are
provided. Such decentralization minimizes bottlenecks whereby workloads
are distributed among multiple hosts. The DCE system further provides
flexibility in the decentralization permitting changing, adding, or
reconfiguring hardware and software without impacting the surrounding
environment. Although closely integrated, DCE's modular structure permits
tailoring DCE configurations by installing DCE servers on computers with
appropriate resources. DCE further harnesses latent computing power
sitting idle in machines on the network by means of remote procedure calls
(RPC) and DCE threads. Moreover, by the aforementioned technique of
locating critical application servers on multiple hosts and replicating
important files onto other systems, critical work may be kept in process
while some systems fail, thereby providing increased availability.
Still further benefits to the DCE environment addressed limitations on
local data storage by providing a distributed file service (DFS) which
provides a single view of all files in an organization both to UNIX
(Trademark of the X/Open Corporation) and non-UNIX systems to all users.
This important DFS aspect of DCE will be hereinafter described in greater
detail. The DCE environment further provides, by means of such DFS, a
database storing the location of all files in the file service. When files
move, the DFS automatically updates the database of the new location.
Similarly, distributed application clients may use the DCE directory
service to locate associated servers, thereby providing services which
track data and programs. Moreover, the aforementioned DCE RPC hides
differences in data requirements by converting data to appropriate forms
needed by clients and servers, thereby accommodating heterogeneous data.
These and other benefits to the DCE systems and, in particular the OSF
implementation, gave rise to an increased interest in adoption of such
systems with a concomitant need for further developments of the components
thereof, such as the aforementioned DFS to be described in greater detail.
Further background on distributed computing and DCE systems may be found
in "Understanding DCE", Rosenberry, Kenney, and Fisher, by O'Reilly and
Associates, Inc., Publishers, copyright 1992 and "OSF's Distributed
Computing Environment", by Ram Kumar, AIXpert, copyright IBM Corporation,
fall, 1991.
An overall high level view of the DCE architecture may be seen with
reference to FIG. 2. It is layered between the operating system 10 and
applications 12. Within DCE, three infrastructure components permeate all
other components, namely the aforementioned remote procedure call (RPC)
and presentation services 14 (which allow developers to program for a
distributed environment as easily as a stand-alone system): security
service, 16 (ensuring against unauthorized access), and management
services 18 (providing utilities to manage DCE services).
Additional components of DCE depicted in FIG. 2 are as follows. A directory
service 20 provides a way for users to name and locate objects, and is
centrally positioned as a keystone of the architecture. It gives
distributed system users a well known, central repository in which to
store information which may be retrieved from anywhere in the distributed
system. A time service 22 provides a consistent view of time in the
distributed environment. Other fundamental services, 24, act as a place
holder for future services. The distributed file services (DES) to be
hereinafter described further, 26, provides a consistent unified view of
all files in the distributed system. A diskless support service, 28,
extends DCE to low-cost, diskless nodes. Other distributed services 30,
will provide services likely to be offered in the future including
spooling services, transaction services, and object-oriented environments.
To build distributed applications, developers need an easy-to-use
programming model, such as the remote procedure call (RPC) 14, to take
advantage of the distributed computing architectures. RPC allows
developers to partition various tasks required by an application into
separate procedure modules which may be executed on different systems.
This offers benefits of an easy-to-use programming model, balanced,
distributed use of computing resources, and the ability to run
applications across diverse software and hardware platforms as previously
described.
Still referring to FIG. 2, threads 32 allow multiple sequential flows of
execution within a single process. Such threads provide a simple
concurrency paradigm maintaining a synchronous model inside each thread
while ensuring that synchronous events take place. In a client-server
environment they allow servers to handle multiple clients simultaneously,
and further allow clients to make multiple requests simultaneously,
thereby providing better service availability. More detail regarding the
RPC model 14 and its interaction with directory services 20 may be
obtained in the aforementioned reference by Kumar.
It will be recalled that the DCE is thus a layer of software which masks
differences between various kinds of hosts. Referring to FIG. 3, this
layering may perhaps be more readily comprehended than in FIG. 2. The DCE
34 layer will be seen as sitting on top of the host operating system and
networking services 10, and offers its services to applications 42
thereabove. From the conceptual model of DCE in FIG. 3, the relationship
may be seen between the DCE distributed services (security 16, directory
40, and time 22 to RPC 14 and thread services 32). RPC and threads are
base DCE services available on systems on which DCE is installed. From the
layered appearance of FIG. 3, it will be more readily appreciated how
similar to applications employing underlying DCE services for distribution
the DCE file service 26 is. It will also be appreciated that the directory
40 actually includes a cell directory service (CDS) component 36 and X.500
directory service 38 (GDS) which programs utilize by calling the X.800
directory service (XDS) application programming interface 40.
Continuing with FIG. 3, it further illustrates how an application 42 may
utilize DCE APIs. A distributed application does not require use of all
DCE APIs but rather only utilizes those which it requires. Thus, in the
illustration of FIG. 3, the application 42 might only require the RPC 14,
security 16, XDS 40, and operating system APIs.
One important aspect of DCE relating directly to the present invention is
the distributed file system (DFS) which will be described now in greater
detail. An overview of DFS may be obtained in "An Overview of the OSF
Distributed File System" by Lebovitz, AIXpert, February, 1992, copyright
IBM and in the previous cite to the article by Kumar, incorporated herein
by reference.
A distributed file system is an application allowing a user on one computer
to easily access files on another. To the user, the distributed file
system appears as a large, local file system.
Such distributed file systems have been in use for at least 20 years, with
early development occurring at the Palo Alto Research Center (PARC) of the
Xerox Corporation, wherein distributed file systems for LANs were
experimented with in the early 1970's.
Most distributed file systems are similar to the original Xerox system.
Files stored on a workstation disk are local files, and those stored on
the central file system are referred to as remote files. When a
workstation user tries to access a remote file, a message requesting
information is sent through the network to the central file system. When
the central file system receives the message, it obtains the requested
information from its disk drive and sends it back to the workstation in
another message. A user modifies a remote file in a similar way. Modified
information is sent to the central file system in a network message. When
the file system receives the message, it writes the modified information
to its local disk.
A major drawback of such distributed file systems is the amount of
resources they utilize. They require more network and remote file system
resources than local sources, creating two problems. First, performance on
the local computer is only as good as the performance of the central file
system, e.g. increasing the power of the desktop computer does not
necessarily increase overall system performance. Secondly, such a system
cannot grow gracefully to an enterprise-wide system.
There are numerous more modern remote file systems presently in use which
include the network file system (NFS) from Sun Microsystems, various
distributed PC network file systems, notably from Apple, Banyan,
Microsoft, and Novell, and various vendor-specific systems such as DECnet
from Digital Equipment Corporation and Domain from Hewlett-Packard
Corporation.
The evolution of computer technology has vastly increased the power of
individual workstations and PCs. However, computers have evolved more
quickly than distributed file systems which do not fully exploit the
wealth of resources available. Several drawbacks accordingly are present
in modern distributed file systems. These include lack of consistent and
uniform file naming space, inconvenient multiple security systems in need
of an integrated approach, data inconsistencies, lack of performance and
scalability, weaknesses in system management and administration,
incompatibility with file system standards, and lack of support for wide
area networks.
As part of the hereinbefore described OSF's DCE, the distributed file
system (DFS) component thereof took a new approach to building an
enterprise-wide distributed file system. It employs modern high
performance workstations and PCs, and exploits performance-enhancing
techniques like caching and replication, thereby distinguishing DFS from
earlier file systems. As but one example, by integrating a distributed
file service 26 with the DCE directory services 20, DFS thereby allowed
users to access files in a consistent manner from different workstations
in a distributed computing environment. These directory services thereby
ensured that the system utilized a uniform naming convention for all files
stored in DFS. As previously noted, DCE directory services are based upon
industry standards, ensuring that every computer resource in the world may
be identified and accessed with a unique and consistent name --such
resources including computers, application services, and files. Referring
to FIG. 4, there is depicted an illustration of how a file located
somewhere in a worldwide DCE file system may readily be located using the
aforementioned global directly service (GDS).
Continuing with the background description of DFS, further information
regarding DFS may be obtained from "The Distributed File System (DFS) for
AIX/6000", document #GG24-4255-00, IBM Corporation, copyright May, 1994.
As previously noted, DFS technology provides the ability to access and
store data at remote sites similar to the technique used with NFS. It
extends the view of a local, and therefore limited in size file system to
the distributed file system of almost unlimited size located on several
remote systems. Several advantages touched on previously are thereby
provided over a centralized system including providing access to files
from anywhere in the world (FIG. 4), higher availability through
replication, and providing users on systems the ability to access data
from a nearly unlimited data space. As such DFS is considered an essential
part of DCE, and was basically an enhanced version of the Andrew File
System (AFS) technology marketed by the Transarc Corporation and recently
integrated into the base DCE technology.
Turning to FIG. 5, the distributed file system from DCE DFS is a collection
of several file systems illustrated at 44-48 located on distributed
systems. All such file systems are mounted into a single virtual file
system space with a single namespace. The end-user thereby has direct
access to all files in this distributed file system without knowing where
the physical files reside. Still referring to FIG. 5, it will further be
noted that a hierarchical structure is provided consisting of directories
and files as is known from other Unix systems. The root of the DFS file
structure is a junction 50 in the DCE naming space, and the multiple file
sets 44-48 may reside on different servers and may be mounted into the DFS
namespace.
Concerning overall DFS operation, DFS is built upon the concept of a
client-server architecture. Turning to FIG. 6, a plurality of clients 52
and servers 54 are shown. The server provides data and the client uses the
data. Communication between the server and client is handled with the
previously described DCE remote procedure calls (RPC) 14. Systems in a DFS
environment which own file systems export them and users on other systems
access such file systems. Such file exporting machines are called DFS file
server systems (e.g. DFS servers 54) and the importing machines are called
DFS client systems (DFS clients 52). A machine can be both a server and
client. FIG. 6 further shows the client/server nature of DFS.
Each DFS server system runs a corresponding file set exporter 54A which
makes file systems 56 available to the DFS file space. DCE cells may have
one or more DFS file servers, with two being shown in FIG. 6. As noted
previously, a system may function as both a DFS client and DFS server.
Each DFS client runs one or more client applications 58 which in turn may
access cache on its respective client.
Turning now to FIG. 7, DFS clients run the cache manager 62, which caches
data from the file exporter 54A in memory or on a local disk, such cache
manager providing the important function of improving performance and
availability. DFS server systems desiring to export file sets must
register their export file sets at a system known as the file set location
server 64. The file set location server maintains a database 66 of all
file sets. This database is utilized to keep track of the physical
locations where file sets are stored. If a DFS client 52 requires access
to one of the file sets, it sends a request first to the file set location
server/database 64, 66 to inquire about the physical location of the file
set. After receiving location information, the client 52 then contacts the
actual particular DFS file server 54 wherein the particular file set or
file system 56 resides.
In addition to the previously discussed DFS machine roles providing the
basic function of DFS file server machines, DFS client machines, and file
set location servers, there are other functions or services which may be
provided by one or more machines well known in the art. These services may
be categorized into machine roles, not all of which are required.
Moreover, a machine may actually serve more than one role, although more
likely they will be spread out throughout a cell. Such machines known in
the art include file server machines, private file server machines, file
set location servers, DFS clients, system control machines, binary
distribution machines, backup database machines, and tape coordinator
machines, all of which are described in further detail in the
aforementioned DFS for AIX/6000 publication.
Numerous basic benefits are provided by DCE DFS over other types of
distributed file systems. These include providing a uniform file space,
caching on the DFS client machine, finer granularity for access control,
ability to establish binary distribution machines, ability to work on
other vendor platforms, built-in backup capability, and diverse
administration options.
As to the DFS relation to DCE, DFS is built on top of the underlying DCE
services as previously described, taking advantage of the lower level
services of DCE such as RPC, security services, directory and time
services. Before DFS may configured on a machine, it requires the
following DCE components be installed, configured, and running in the
cell: security server, director server, and DCE time servers, all of which
are also further described in detail in the aforementioned AIX article.
Referring now to FIG. 8, it first illustrates the required DCE components
previously mentioned for running in a cell before DFS may be configured on
a machine, namely the security server 62, cell directory server and DCE
time servers 66. The further purpose of FIG. 8 is to not only show the
aforementioned components for a DCE configuration, but additionally the
DFS components which have been added to implement a DCE DFS cell, thereby
also illustrating the different DFS machine roles. As previously
described, DCE cell requirements are for at least one cell directory
server 64, one security server 62 and at least three DCE distributed time
servers 66. However, these are DCE requirements for a cell and not DFS
requirements. The DCE cell may operate with the above requirements.
However, in order to add the DFS capability to the DCE cell, the following
additional components are required. First, all DFS clients 68 and servers
such as DFS file servers 70 must be minimally configured as DCE clients.
Secondly, at least one file set location database machine 72 is required
and at least one system control machine 74 per administrative domain. A
backup database machine and tape coordinator 76 are optional. Further
details regarding these additional components to implement DFS on DCE may
also be found in the aforesaid AIX publications.
It is at times desirable to operate differing operating systems in a DCE
environment such as the OS/2 (Trademark of the IBM Corporation) operating
system provided by the IBM Corporation. Such file systems typically (and
specifically in the case of OS/2), include what is known as "attributes"
of various types such as "extended" attributes and "file" attributes to be
hereinafter described in great detail. One problem with the widely
accepted OSF DCE DFS file system is that it does not provide for native
support for attributes such as the OS/2 style attributes. Nevertheless,
this functionality must be provided for OS/2 clients prior to the
availability of such support for these attributes through DFS protocols.
The OS/2 client expects to attach standard file attributes (FAs) directly
to a file. Moreover, OS/2 clients further expect to be able to retain
additional information about files and directories in named entities known
in the art as "extended" attributed (EAs). However, the OSF DCE DFS knows
nothing about OS/2-specific FAs or EAs, and accordingly a need arose to
accommodate such capability. However, an additional constraint on the
system design was that such attributes must not be visible to the OS/2 DFS
clients except through the normal OS/2 application programming interfaces.
In other words, they must not be visible in the namespace which OS/2 DFS
clients may access.
OS/2 extended attributes were implemented in the file allocation table
(FAT) file system by storing all the EA data for a single OS/2 drive in a
single file in the root directory of the drive. However, in addition to
performance and accessing problems associated with a single file
containing all EA data, the FAT solution was unworkable in DCE DFS
environments because of security requirements. The DFS solution requires
users to have the proper permission before accessing EA/FA data. This is
true even if the user is on a non-OS/2 DFS system which does not support
EAs. Grouping EA data from multiple users into a single file, as might
otherwise be required without the invention, would render the provision
for users to have proper permission unfeasible on a non-OS/2 system.
Moreover, the single file concept, as previously noted, would give rise in
many instances to the performance bottleneck noted when it is considered
that hundreds and perhaps thousands of distributed file system users might
need access to that single file at the same time.
The foregoing problems regarding the DFS file system not providing for
native support for file and extended attributes such as those of the OS/2
operating system were addressed in our copending U.S. patent application
Ser. No. 08/355,868 now U.S. Pat. No. 5,617,568 entitled "SYSTEM AND
METHOD FOR SUPPORTING FILE ATTRIBUTES ON A DISTRIBUTED FILE SYSTEM WITHOUT
NATIVE SUPPORT THEREFOR" and which is incorporated herein by reference.
Yet other problems, however, are presented by employing distributed file
systems such as the aforementioned DFS with certain operating systems
including the previously referenced OS/2 (TM) operating system.
DFS supports pathname syntax which differs from that of certain operating
systems. This, in turn, presents problems for programmers porting DFS
client code to such operation system platforms, e.g. how might a user of
such operating systems be enabled to reference a file or directory of a
distributed file system such as DFS using this unsupported syntax?
Some operating systems provide for installable file systems (IFS) to
facilitate use of other file systems with the operating system as, for
example, in the case of OS/2 operating systems. However, even with the
addition of such a facility of IFS for a DFS client, only the pathname
styles of the operating system itself will be recognized by the operating
system.
Many file systems attach at the top of the system's file space. However, in
the case of OS/2 and other file systems, if an attempt is made to attach
at the top of the DFS tree, for example, the operating system user would
have to deal with unfamiliar syntax of the file system, such as
/. . . /cell.name/fs/<dir1>/<dir2>/<filename>.
SUMMARY OF THE INVENTION
It is therefore an object of the invention to facilitate an operating
system user's ability to reference objects in a distributed file system
having an incompatible namespace.
It is a further object of the invention to provide compatibility between
DFS namespaces and operating system pathname syntax not supported in the
DFS.
It is yet another object of the invention to facilitate a programmer's
ability to port DFS client code to certain operating system platforms.
According to the invention, these objects are accomplished by first
associating a DFS pathname prefix such as /. . . /cellname/fs with each
drive letter that is attached to a DFS IFS driver, such as via the
"dosFSATTACH" command in the case of the OS/2 DFS implementation.
Before an IFS driver is used, an application program issues a "dosFSATTACH"
command in order to associate at least one OS/2 drive letter with that
particular IFS driver. The "dosFSATTACH" command which is thereby issued
also carries a DFS pathname prefix within a data buffer. The IFS driver
services the "dosFSATTACH" command by validating the existence of the DFS
pathname prefix, and thereafter stores such pathname prefix into an
internal table where it is associated with the attached OS/2 drive letter.
All file system requests which are later received by the DFS client IFS
driver, and which carry a pathname containing that drive letter, will have
their file specifications edited by the DFS code prior to processing. The
drive letter in the pathname is replaced by the DFS pathname prefix from
the IFS driver's internal table. All backward slashes (".backslash.") in
the OS/2 pathname are then converted to forward slashes ("/").
In this manner, the effect is to route OS/2 drive letters at particular
points within the DFS namespace. The operating system user is thereby
allowed to reference DFS objects relative to that point in the namespace,
utilizing the operating system's pathname syntax that the user is
comfortable with.
Whereas the embodiment just described is with respect to the DFS file
system, the invention is not intended to be so limited and is thus
applicable to distributed file systems generally having no name
restrictions other than those of the POSIX IEEE 1003 standard and thus
includes the aforementioned NFS file system.
Moreover, for convenience, when the acronym DFS has been used herein, the
DCE DFS file system has been intended, whereas when the "distributed file
system" term is herein utilized, the more general file systems thus
described are intended.
BRIEF DESCRIPTION OF THE DRAWINGS
The foregoing and other objects, aspects, and advantages of the invention
will be better understood from the following detailed description of the
preferred embodiment of the invention with reference to the accompanying
drawings, in which:
FIG. 1 is block diagram of a typical individual computer site such as a PC
or workstation forming a component of a DCE DFS environment in accordance
with the invention;
FIG. 2 is a conceptual block diagram of the DCE computing environment
architecture;
FIG. 3 is another illustration of the DCE architecture of FIG. 2 depicting
the layered aspect thereof;
FIG. 4 is an illustration of the global nature of the DCE file system;
FIG. 5 is a block diagram illustrating a single image view of the DFS
namespace;
FIG. 6 is a block diagram of a DFS client and server file server operation;
FIG. 7 is a block diagram illustrating how a DFS client locates a DFS
server;
FIG. 8 is a block diagram illustrating a fully configured DCE DFS cell;
FIG. 9 is a block diagram illustrating extended attributes of a file;
FIG. 10 is a block diagram illustrating an OS/2 DCE DFS client structure;
FIG. 11 is an example illustrating how EAs would be stored;
FIG. 12 is a flow diagram illustrating the use of EAs to support file
attributes on a distributed file system;
FIG. 13 is a flow diagram of a process implemented by a computer system in
accordance with the invntion whereby a table is built correlating
operating system drive letters and file system namespace syntax.
FIG. 14 is a flow diagram of a process implemented by a computer system in
accordance with the invention for processing a file system request whereby
compatibility is provided between distributed file system namespaces and
operating system pathname syntax not otherwise natively supported in the
namespace.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
It will be noted that it was a feature of the invention disclosed in our
copending U.S. patent application Ser. No. 08/355,868 entitled "SYSTEM AND
METHOD FOR SUPPORTING FILE ATTRIBUTES ON A DISTRIBUTED FILE SYSTEM WITHOUT
NATIVE SUPPORT THEREFOR" filed Dec. 14, 1994 now U.S. Pat. No. 5,617,568,
to provide for file attributes for a particular operating system in a
distributed file system environment which does not have native support for
such attributes. In order to more fully understand the present invention,
an understanding of attributes of files in an operating system may be
helpful as a related instance of the problems which arise from commingling
operating systems and file system each having differing characteristics
such as syntax. Such attributes and provision for namespace compatibility
will be discussed with respect to the OS/2 operating system. However, the
invention is not intended to be so limited to a particular operating
system, but rather may be readily generalized to handle and provide
compatibility for many given operating systems on a distributed file
system. Thus, the invention is not intended to be limited to the OS/2
embodiment herein illustrated.
For background and detail on the nature of attributes and, more
particularly, extended attributes (EAs) and file attributes (FAs) as they
relate to the OS/2 operating system, reference may be made to chapters 4
and 5 of the OS/2 2.0 Programming Guide, Vol. 1.
For present purposes, however, it will be appreciated that certain file
systems such as the aforementioned OS/2 file system, maintain a standard
set of information on file objects which typically includes the name and
size of the file, date and time the file object was created, last accessed
and last written to.
Applications may, however, attach additional information to a file object
in the form of an extended attribute. There may be multiple EAs associated
with one particular file object and, because of their flexibility, almost
any information about the file may be stored in one. These EAs may be
utilized to describe a file object to another application, to the
operating system, and to the file system that is managing that object. The
information contained therein may be utilized to store notes on file
objects, (e.g. the name of the creator), to categorize file objects (for
example, source, samples, icons, bit maps), to describe the format of data
contained in the file object (for example a data record), or to append
additional data to the file object.
An application uses extended attributes to provide a description of a file
or directory. However the application may not actually place the
description in the file or directory itself. Extended attributes
associated with a file object are not necessarily part of the file object
or its data. Rather, they may be stored separately from the file they are
linked to and thereby referred to as being "attached", and the file system
manages the storage and maintenance of such EAs.
The value of an EA may be text, a bit map, binary data, or the like. The
operating system does not check data associated with an EA. The
application which creates the EAs and the application that reads them must
recognize the format and meaning of the data associated with a given EA
name. Applications may examine, add, and replace EAs at any time. A file
may have any number of EAs, as illustrated in FIG. 9. In the OS/2
implementation of EAs, each EA may be up to 64 KB in size, and the sum of
all EAs for a file must not exceed 64 KB.
As an illustration of EAs, with further reference to FIG. 9, an
illustrative file entitled "my.sub.-- file", 80, is shown having numerous
EAs 82-94 with the associated names and values shown in Table 1.
TABLE 1
______________________________________
NAME VALUE
______________________________________
FILE TYPE Data for My.sub.-- App
HISTORY Created by myself 1989
VERSION 1.00
COMMENTS Cannot be used with any other app
KEYPHRASES my.sub.-- own.sub.-- key.sub.-- phrases
SUBJECT A brief summary of the file's
contents or purpose
EXTRA DATA I can store additional data for
My.sub.-- App in an extended attribute
______________________________________
So that EA data may be understood by their so applications, conventions
have been established for naming EAs and indicating the type of data they
contain. Such EAs associated with a file object may not be part of the
file object or its data but rather are "attached" as will be hereinafter
described.
Referring to Table 2 which follows, it will be apparent that in the OS/2
implementation EAs may contain any type of data as shown by the variety of
data types 96 and associated descriptions 98. All user-defined data types
are length-preceded, meaning that a word indicating the length of the data
in bytes precedes the data. As an example, a representation of the ASCII
string "Hello" would be as follows: EAT.sub.-- ASCII 0005 Hello.
TABLE 2
______________________________________
Extended Attribute Data Types
Data Type (96)
Value Description (98)
______________________________________
EAT.sub.-- BINARY
FFFE Binary (non-text) data; the first
WORD following the data type
specifies the length of the data
EAT.sub.-- ASCII
FFFD ASCII text; the first WORD
following the data type specifies
the length of the data
EAT.sub.-- BITMAP
FFFB Bit map data; the first WORD
following the data type specifies
the length of the data
EAT.sub.-- METAFILE
FFFA Metafile data; the first WORD
following the data type specifies
the length of the data
EAT.sub.-- ICON
FFF9 Icon data; the first WORD
following the data type specifies
the length of the data
EAT.sub.-- EA
FFEE ASCII name of another EA that is
associated with the file. The
contents of that EA are to be
included into the current EA.
The first WORD following the
data type specifies the length
of the data.
EAT.sub.-- MVMT
FFDF Multi-Valued, Multi-Typed data -
two or more consecutive extended
attribute values. Each value
has an explicitly specified type.
EAT.sub.-- MVST
FFDE Multi-Valued, Single-Typed data -
two or more consecutive attribute
values. All values have the same
type.
EAT.sub.-- ASN1
FFDD ASN.1 field data; an ISO standard
for describing multivalue data
streams
______________________________________
Because many applications utilize text, bit maps, and other binary data in
EAs, standard names have been adopted to identify such formats for a
common set of standard EAs although applications are not limited to such
EAs and may define their own application-specific EAs. Such standard EAs
in the OS/2 convention have a dot as a prefix identifying the EA as a
standard EA. The leading dot is reserved, so that applications should not
define EAs commencing with a dot. Also, EAs commencing with the characters
$, @, &, or + are reserved for system use. Standard EAs which have been
defined include .ICON, .TYPE, .KEYPHRASES, and the like more fully
described in the previously noted IBM programmer's manual.
Now that a description of DCE, DFS, and the EA and FA aspects of OS/2 have
been described, a specific DCE DFS client/server system will be described
in greater detail with reference to FIG. 10 in which the invention may be
implemented in a preferred embodiment. It will be noted from FIG. 10 that
the DFS client 96 is implemented executing the OS/2 operating system and
the DFS server 98 is implemented employing the AIX (TM) Unix-based
operating system of the IBM Corporation. It will also be noted that the
client 96 employs the OS/2 installable file system facility well known in
the art, thereby removing the need for intercepting file system calls at
the user level or kernel level above and below line 100, respectively. The
cache manager 102, which handles the manipulation of remote files on the
local workstation disk, is implemented at the user level above line 100. A
driver on the client machine 96 is attached to a DFS file system driver
104 in the kernel below line 100. An IFS file system request router 106
directs file system requests to the DFS FSD 104 if the requests are
associated with the drive to which the DFS FSD is attached. The FSD 104
then routes the file system requests to the DFS cache manager. The OS/2
cache manager (CM) 102 has a file system request administrator (VENUS) in
the user space to receive requests from FSD 104. VENUS, 102, in turn
includes a pool of threads to process such file system requests. A thread
will be allocated to a file system request received from the FSD 104. Such
VENUS thread will invoke appropriate mapping routines in CM 102 to
translate the FSD 104 requests into CM vnode operations acted upon by the
OSF CM 104A through the network by means of the previously discussed
client and server remote procedure calls (RPC) 106, 108, respectively.
Finally, with respect to FIG. 10, it will be seen that in the client
implementation, conventional DOS or windows calls will be issued or
received by user applications 110 executing in the client 96 space, such
calls being passed between the user application 110 and the IFS file
system request router 106.
Clients, such as those of OS/2 and AIX, typically expect files and/or
directories to contain attributes previously described such as "Archive",
"Hidden", "System", "Icon", etc. It will be recalled from the foregoing
that these attributes indicate characteristics of the file or directory
which may be required by an application. In such operating systems as OS/2
and AIX, their file systems are constructed so that the attributes are
"attached" directly to the data as contrasted with the case of DFS herein
described wherein there is no provision for such ancillary extended
attribute data. Thus, the problem arises that if EAs and FAs may not be
attached to a file directly (e.g. the norm in a file system) then how may
such attributes associated with an operating system be attached and
referenced in the context of another file system such as DFS having no
native support for these attributes. In other words, in essence, FAs in
OS/2 for example, are attached in part of the corresponding file, whereby
when the file is moved, the FAs accompany it. This is not true in DCE for
example, so that when a file is copied from a DCE server, heretofore the
FAs or other attributes which may be crucial to the application would not
accompany the file. Thus, a technique was needed for attaching these
attributes in a DCE context.
Numerous other related problems have persisted. For example, when a "dir"
is performed in OS/2 the user will see files in the directory but
typically not related attribute files as a result of normal OS/2 APIs. In
any implementation solving the problem of attaching attributes in DFS, it
is highly desirable to retain this user convention of not displaying
attributes unless explicitly commanded to do so, e.g. it was desirable
that such attributes not be visible in the namespace which OS/2 DFS
clients could access so that the OS/2 DCE user would see only what would
be normally expected on a native OS/2 operating system and not the
ancillary files which a typical OS/2 user would know nothing about. Thus,
in summary, as a practical example of a typical problem created by current
systems, when files copied from a native OS/2 file system (which supports
EAs and FAs) are copied to a popular distributed file system such as NFS,
which does not support such EAs and FAs, they get deleted. However,
applications for example may require such attributes which will
accordingly break if attempted to be run without their respective
attributes.
One attempt to solve the problem was to attach attributes by internal file
handles. When a file system is on line and active in DFS, such file
handles on a server are meaningful and valid. However, it soon became
apparent that their utility in attaching attributes was lost once the
system was backed up which is typically done. Internal identifiers or file
handles may be efficient, but once the DFS file system is backed up and
taken off line, when brought back on line, such files and associated file
handles get reassigned as the files are brought back in.
In other words, a file "X" might have a handle name "27" when the DES file
system is backed up and brought back on line, it would however be assigned
the next available internal number, (e.g. although we named it 27, after
the server was backed up and brought on line the file might thereafter be
designated "38", whereupon the server will no longer know, for example,
about the previously identified file attribute).
Turning now to FIG. 11, a technique for storing attributes is illustrated
by means of a representative example. It will be assumed a file "X" in
directory "Y" 112 exists with a number of EAs 114, such as "icon", "ascii"
and "type". For this file "X" in directory "Y" 112 in the DFS namespace
for which EAs must be created, a subdirectory 116 is created in directory
"Y" 112 such as .*OS2DFS.sub.-- EAs.
Next, a directory under the .*OS2DFS.sub.-- EAs subdirectory 116 is created
shown at reference numeral 118 whose name is the file's name (X). Each of
the EAs 114 associated with the file X will be placed under the "X"
subdirectory 118, with each of the attribute names such as "Icon" being
the file name under the /X subdirectory.
A departure in the description relative to FIG. 11 must now be made with
respect to "critical" EAs. A field in an EA may be user-specified as being
"critical". As to the significance of "critical" designations,
applications for example may have to access an attribute and its
associated file in order to perform some task where the application may
fail. Thus, we must be able to identify quickly and inform the calling
function whether the attribute is critical.
As an example, in the REXX language, command files in some cases are
compiled to operate efficiently. Compiled versions are extended attributes
attached to the command version. Instead of carrying two versions of a
command file, a compiled binary is "attached" as an EA. If it is specified
that all REXX command files are desired to run an application, which would
thus include the compiled version of commands, such commands would be
"critical" to the application, e.g. if not attached, the application
calling for them could not execute.
With the foregoing in mind, returning now to FIG. 11, if an EA is
determined to be critical, it will be so marked by preceding its file name
with a "?". For example, a conventional non-critical EA with an attribute
name of "ICON" may be seen in FIG. 11 stored as a file name "ICON".
However, an EA which might be deemed critical, such as "TYPE", would be
indicated as "?TYPE" as also shown in FIG. 11. It will be noted that OS/2
extended attribute names must follow the same conventions as OS/2 file
names, and therefore "?" and "*" are not valid for use in names on OS/2.
EA file naming in accordance with the invention becomes more complicated
when EA names reach a maximum length. One assumption is that the maximum
length attribute name case (with collisions) is seldom if ever going to
happen. If the attribute name is the maximum length (for example, 256
characters), then the first two characters of the attribute name will be
replaced with a "??". The original name of the attribute will be stored in
the file header. Thus, whenever a file name is encountered with a "??" at
the beginning, this is a signal to the DFS to look in the file header for
the original name of the attribute. Because the original unique attribute
name has been changed of course, a possibility arises of file name
collisions. For example, two critical EAs with attribute names
"A------maxlength . . . " and "B------maxlength . . . " would both have
file names of "??----maxlength . . . ". Such potential collisions will
therefore be resolve by adding another "?" to the file name. Thus, in the
foregoing example, the second EA would have a file name of "???--maxlength
. . . "
Continuing with the example of FIG. 11, operating systems such as OS/2 may
provide for many EAs per file. When performing a "dir" function in OS/2,
the corresponding call goes through the API and queries the file system
for each file to determine the file size and size of the EAs. In the
implementation being herein described, it was undesirable to read all file
headers for EA critical status, and size, and accordingly this information
was pulled out for all EAs and cumulated or placed in a single file,
thereby providing a performance benefit. Thus, in summary on this point,
in order to provide efficient access to the total EAs size and number of
critical EAs for a file, an additional file 120 is created for each file
such as file X and placed under the .*OS2DFS.sub.-- EAS/X directory. This
file will have a form and be named *N*C, wherein N is the total size in
bytes of all the EAs and C is the number of critical EAs for the file.
Once again, the "*" at the beginning of the name is used to prevent
conflict with EA names.
Using the example of FIG. 11, it will be noted that the file 120 includes a
number "70" followed by a number "1". The 70 will be seen to be the sum of
the sizes of the attributes ICON, ASCII, and ?TYPE, e.g. 10+40+20. The "1"
indicates that the number of critical for file "X" is 1, e.g. the ?TYPE
critical EA.
In like manner, a subdirectory/Z might be included under the directory 116
for all file "Z" EAs shown at reference numeral 122, with the EAs therefor
shown at 124.
It will be appreciated that EAs may be attached to directories as well as
files. In the example given in FIG. 11, the illustration would be
essentially the same if "X" was a directory rather than a file.
Furthermore, attaching EAs to the root directory is the only exception to
the scheme described in FIG. 11. The directory .*OS2DFS.sub.-- EAs will be
created in the root itself since there is not a parent directory.
It will be noted that the directory name such as .*OS2DFS.sub.-- EAs is
inpermissibile in OS/2 applications. The OS/2 kernel will not permit this
across the file system API, but will try to substitute something for the
asterisk and will be unable to find any matches but the asterisk itself.
This is to be contrasted with, and thus very unlike, the Unix model, where
the file system will accept any value for a name, and the various shells
are responsible for metacharacter substitutions. In effect, what is being
accomplished is the hiding of EAs and FAs in an opaque part of the DFS
namespace, at least as far as OS/2 applications and users are concerned.
This directory wherein the EAs reside is thereby only "semi-visible" to
Unix users. The ameliorating circumstance is that it appears like an
application configuration file that even novice Unix users tend to not
access or alter. The directory will not be visible because it starts with
a ".", unless the Unix user specifically requests that it be seen. Even
then, however, DCE DFS provides security support requiring a user to have
the proper permission before being allowed to access to a file or
directory. This security support has been extended for EA/FA data and
files. It requires the same permission to access EA/FA data as is required
to access the file to which the EA/FA data is associated. Even if the Unix
user has requested viewing of the directory, no user data is visible
unless the user would also be able to access the data as an OS/2 user.
Turning now to FIG. 12, depicted therein is a flow diagram of how a system
such as that of FIG. 10 might employ the EA filing technique beneficially
which was just described with reference to FIG. 11.
First it will be assumed that an application has made a call for a "dir"
function which may include a need to know how big the file is, and
information regarding the EAs and FAs attached thereto. The OS/2 operating
system would examine the call, and detect that it related to a file in the
file system managed by DFS by means of the DFS file system driver,
whereupon it is necessary to process the request. This information request
about attributes is shown at block 126.
The system would then query at 128 whether the previously described
.*OS2DFS.sub.-- EAs directory exists. If not, the left branch is executed,
indicating at block 130 that no EAs are attached to files in the file
system. Consequently, a query for size and/or query for whether critical
EAs exist corresponding to the file name "X" will return 0, shown at 132.
If, on the other hand, the directory in response to decision block 128 is
determined to exist, flow exits to the right to a next decision block 134.
At block 134, a query is made as to whether a subdirectory/X having the
same name as the file name (X) exists. If not, the flow exits the left
path from block 134 indicating as shown at block 136 that EAs are attached
to some files in the file system but not file "X", whereupon a 0 is
returned, 138.
If on the other hand, in response to the decision block 134 it is
determined that such a subdirectory/X exists, flow exits to the right of
block 134, whereupon files in the subdirectory/X are read, 140.
Next, a determination is made at decision block 142 of whether the size of
the EAs or critical status has been queried. If not, the EA files (ICON,
etc.) are simply read and passed back to the caller, 144. If, on the other
hand, the size and/or critical status of EAs has been requested, flow
exits to the right of block 142 whereupon the parameter *n*c is returned
at block 146. It will be recalled that the "n" in the parameter provides
the desired EA size and the "c" provides the count of critical EAs
associated with the /X subdirectory. Control is thereafter returned at
block 148.
Now that a description of storing and utilizing stored EAs in accordance
with the invention has been made, attention will focus to the related
problem of supporting file attributes, FAs. It will be recalled that OSF
DCE DFS also does not have native support for OS/2 file attributes, yet
this functionality must, in like manner to EAs, be provided for OS/2
clients prior to any future availability of support through DFS protocols.
This function will be provided as follows with reference to Tables 3 and
4.
For OS/2 FAs having similar semantics to existing DCE DFS file attributes,
existing DCE. DES fields and interfaces will be utilized to access and
represent the particular attribute. The OS/2 FAs "Hidden", "System", and
"Archive" apply only to OS/2 DFS users and will be represented using the
schema hereinafter described.
For a file "X" in directory "Y" in the DFS namespace for which OS/2 FAs
must be created, a directory ".*OS2DFS.sub.-- FAs" will be created in
directory "Y". Similarity to directory 116 in FIG. 11 with respect to EAs
will be noted. Also similar to the approach of FIG. 11, the FA's
attributes will be represented by a file under .*OS2DFS.sub.-- FAs. The
file will be named "FILENAME*V" where "FILENAME" is the target file's name
without a path, and "V" is a value representing the file's OS/2 attribute
settings. It will be noted that because of size restrictions, the values
for V are not directly mapped to the OS/2 attribute values. In other
words, an internal table is provided indicating what the value means. For
example a "6" could correspond to a "Hidden" value of 4 and "System" value
of 2.
When initially creating FAs, if the FA values requested by the caller match
the defaults shown in Table 3, then no FA directories or file will be
created. When searching for a file's FAs and no FA directories or file is
found, then the default FA values will be assumed, shown in the right
column of Table 3.
Shown in Table 4 is a representative example indicating how such FAs will
be stored. It will be assumed that a file "X" in directory "Y" exists with
FAs of "Hidden" and "System". The first line of Table 4 indicates the
representation of file "X" in directory "Y". The second line of Table 4
indicates the subdirectory which contains all FAs for directory "Y".
Finally, the third line of Table 4 indicates a file "X*6". From the
foregoing, it would be apparent that this indicates that the FAs "Hidden"
and "System" exist, as designated by the 6, for file "X".
TABLE 3
______________________________________
File Type Default value of attributes
______________________________________
File Archive 0.times.20
Directory Subdirectory 0.times.10
______________________________________
TABLE 4
______________________________________
/y/x File x in directory y
/y/.*OS2DFS.sub.-- FAs
Contains all FAs for directory y
/y/.*OS2DFS.sub.-- FAs/x*6
FAs Hidden and System for file x
______________________________________
FAs may also be attached to directories. The example with reference to
Table 4 would be the same essentially if "X" was a directory. Also,
attaching FAs to the root directory is the only exception to the scheme
described above as is the case with EAs. The directory .*OS2DFS.sub.-- FAs
will be created in the root itself since there is no parent directory.
The components of a representative computer system such as a PC or
workstation in which the invention may be implemented will be described
which may be utilized by a user as part of a component of the system of
FIG. 10.
The clients and servers described herein may be preferably implemented with
workstations such as an IBM.RTM. RISC System/600.RTM. computer. A
representative hardware environment is depicted in FIG. 1 which
illustrates a typical hardware configuration of a workstation in
accordance with the subject invention having a central processing unit
(CPU) 10A such as a conventional microprocessor, and a number of other
units interconnected by a system bus 12A. The workstation shown in FIG. 1
includes a random access memory (RAM) 14A, read only memory (ROM) 16A, and
I/O adapter 18A for connecting peripheral devices such as disk units 20A
to the bus, a user interface adapter 22A for connecting a keyboard 24A,
mouse or other pointing device 26A, speaker 28A, microphone 32A, and/or
other user interface devices such as a touch screen device, etc. to the
bus. The system further includes a communication adapter 34A for
connecting the workstation to a data processing network, and a display
adapter 36 for connecting the bus to a display device 38A. The workstation
has resident thereon an operating system such as the IBM AIX.RTM.
operating system.
FIG. 14 illustrates a flow diagram of code to be implemented on the systems
of FIG. 1 and 10 for handling file system requests in accordance with the
invention.
First a high level of an implementation of the invention will be provided,
followed by a more detailed description with reference to FIGS. 13 and 14.
DFS supports a pathname syntax as follows:
/ . . . /cell.name/fs/<dir1>/<dir2>/<filename>.
Further detail regarding naming conventions in DFS and DCE cells may be
found on page 7 of the "DFS for AIX/6000" publication and on page 32 et
seq of the "Understanding DCE" publication hereinbefore referenced.
It will be appreciated that this pathname syntax is substantially different
from that of the pathname syntax supported by other operating systems such
as the OS/2 operating system. Accordingly, a serious problem was presented
for programmers who were involved in porting the DFS client code to such
an operating system platform. More specifically, the problem presented was
how an operating system user of, for example, OS/2, would be able to
reference a file or directory utilizing this unsupported syntax.
A conventional mechanism for supporting new file system types has already
been discussed with reference to the mechanism in OS/2, namely the
provision for an installable file system (IFS). This mechanism was
discussed with reference to FIG. 10 and, in particular, the IFS file
system request router 106 thereof. Even with the addition of such a
facility as IFS on a DFS client, only OS/2-style pathnames continue to be
recognized by the OS/2 operating system. The solution offered to this
problem by the present invention was to associate a DFS pathname prefix
(e.g./ . . . /cellname/fs) with each drive letter that is attached (via an
appropriate command such as the "dosFSATTACH").
Before an IFS driver can be used, an application program must issue such a
command as "dosFSATTACH" to associate at least one driver letter from the
operating system such as OS/2 with that particular IFS driver. The command
such as "dosFSATTACH" which is issued to the DFS client IFS driver also
carries a DFS pathname prefix within a table defined in a data buffer. The
IFS driver services the "dosFSATTACH" by validating the existence of the
DFS pathname prefix and storing the pathname prefix into the previously
mentioned internal table in the buffer, where it is associated with the
attached OS/2 driver letter.
All file system requests which are later received by the DFS client IFS
driver and which carry a pathname containing that drive letter will have
their file specifications edited by the DFS code prior to processing. The
drive letter in the pathname is replaced by the DFS pathname prefix from
the IFS driver's internal table. All backward slashes in the OS/2 pathname
are then converted to forward slashes.
It will be appreciated from the foregoing that the effect of the invention
is to route the OS/2 driver letter at particular points within the DFS
namespace. Moreover, the invention thereby permits the OS/2 user to
reference DFS objects relative to that point in the namespace, utilizing
the OS/2 pathname syntax that the user is most comfortable with.
Many file systems attach at the top of the file space, however this is not
the normal way in which the OS/2 and other operating systems use the
available space. In accordance with the invention, multiple drives may be
provided and, for example, a drive may point to the top of the file space.
However in accordance with the invention it may be mounted further down in
the namespace wherever desired. In operation, a user, for example, might
enter a D: in order to switch to the D drive. A call would then be
intercepted by the file system request router 106 (FIG. 10) originating
from the application 110. This call signifies the desire to attach the
drive D to a certain position in the file space. The operating system
would normally be trying to attach a path to a file system to a drive
letter whereby normally the entire file space would get attached to the
drive D. In DFS, that would of course be the entire DFS file system if
attached at the top of the tree. Normally, however, with the large file
systems provided by DFS, the desire in fact may to attach down in the
tree. Accordingly, instead of attaching at the top, when such a request is
routed to the DFS file system driver 104 of FIG. 10, a table is kept in
accordance with the invention of where the user actually desires to
attach.
Therefore, it is a feature of the invention to store, for a particular
drive, the location in the DFS namespace where it is desired that the D:
drive be attached. The next time a request is received for a drive, it is
not simply assumed that what is desired is the location at the top of the
DFS namespace. The aforementioned table is therefore utilized to decide
where to route the request within the DFS namespace.
As previously discussed regarding the problem addressed by the invention,
it will be recalled that with respect to OS/2 operating system user or the
user of other operating systems, such a user may not be conversant and
comfortable with a distributed file system syntax such as that of DFS. If
the user were attached at 25 the top of the DFS tree, he or she would have
to deal with the "/ . . . " and other unfamiliar syntax. Accordingly, in
accordance with the invention, it permits the user to attach further down
on the tree by means of the table retained in the client 96. When a
request is received for a file on a drive, this request is converted from
a drive-oriented request to the DFS namespace syntax before it is routed
to the server shown at reference numeral 98 of FIG. 10. This conversion is
performed in the DFS file system driver 104 wherein the lookup table
resides. Thus, by the time the request is routed to the right side of the
diagram of FIG. 10 to the server 98, the client name has been transformed
to the corresponding DFS name and then transported to the server. When a
drive is to be attached, a request for such action indicates the drive to
be attached and what is desired to be attached to it. In the case of a LAN
server, for example, this would include the domain or server name; in the
case of the NFS file system, a mount point, and in the case of DFS, a
string utilizing DFS syntax. Such a request must be "validated" by
determining if the specified pathname exists, e.g. in the case of the LAN,
verifying the server is there, or, in the case of DFS, determining whether
a valid point in the namespace has been specified. The pathnames thus
specified in accordance with the invention are tracked in an internal
table. More particularly, the pathname prefix specified in a request to
attach a drive is associated with that drive letter and retained in the
table. In this manner, when a user references a particular drive letter,
the internal table has retained the original request. Once the table is
thereby established, all file system requests received by the IFS driver
which carry the pathname that has the drive letter will be modified before
processing. In other words, the drive letter in a request will be modified
before further processing by the server whereby the drive letter is
replaced by the pathname prefix previously saved in the internal buffer.
In this manner, every time the drive is referenced in a path, it will be
modified based upon the contents of the internal table for that drive to
be an actual DFS path instead of the conventional drive syntax of the
operating system.
With the foregoing in mind, turning now to FIG. 13 and 14, these flow
diagrams may be more readily understood. First, regarding FIG. 13, this is
an illustration of a flow diagram of program code in accordance with the
invention to be implemented whereby the previously noted internal table is
constructed. First, it will be assumed that an appropriate user
application 110 of FIG. 10 has issued a "dosFSATTACH" or like command to a
DFS client IFS driver to be routed by the router 106. The purpose of such
a command is to associate one or more OS/2 drive letter such as,
illustratively, driver letter "X" with a particular IFS driver. The
"dosFSATTACH" command thus carries the DFS pathname prefix.
Upon the request being generated to associate the drive letter with the IFS
driver, 150, the process then performs a check of whether the DFS pathname
prefix in the request is valid, 152. If not, the routine ends, 156. If, on
the other hand, when the IFS driver services the DOS attach command, the
IFS driver has validated existence of the DFS pathname prefix (e.g.
verified that a valid point in the file system namespace exists), the
process exits the left branch from box 152. At this point, the pathname
prefix corresponding to the request is stored in a table in an internal
buffer in the DFS file system driver 104. This prefix is stored in the
table associated with the corresponding attached OS/2 drive letter "X" by
the client 96. The purpose for doing this is that when the user references
the particular drive letter again, there is an internal table containing
what was originally asked for which may be thereafter utilized once the
table is established in the manner of the invention.
After the table has been established, turning now to FIG. 14, there is
illustrated a flow diagram of code in an implementation of the invention
which would take advantage of this feature in processing a file system
request. More specifically, referring to FIG. 14, it will first be assumed
that a file system request has been generated, 158, from an application
110 for a file on a particular drive whereby this drive is referenced in a
path. After generating the request 158, it is received by the DFS client
IFS driver 106, shown at box 160. Next, a check is made to determine if
the request carries a particular pathname containing the drive letter "X"
shown at box 162. If not, the routine ends, 166. If, on the other hand,
the check in box 162 reveals that the pathname is present in the request,
the process exits to the left of box 162, whereupon the file specification
is modified or edited by the DFS code before further processing, shown at
box 164.
This process of modifying or editing the file spec is essentially the step
of transforming the client name of the request to the DFS name before it
is transported to the server side 98 of FIG. 10. This is done by replacing
the drive letter in the request by the pathname prefix previously saved in
the internal buffer, which is the actual DFS path rather than the
conventional drive syntax. As shown by the dotted lines in FIG. 14, the
more detailed steps effected in such editing are shown in such alternate
path. Specifically, the previously appropriate entry therein, the drive
letter in the generated table in accordance with FIG. 13 is searched,
shown at block 168. In response to location of an pathname "X" is replaced
with the DFS pathname prefix from the IFS driver's internal table, block
170. Finally, the back slashes in the operating system pathname in the
request are converted to forward slashes 172, whereupon further processing
of the request by the server is permitted as shown at block 174.
While the invention has been shown and described with reference to
particular embodiments thereof, it will be understood by those skilled in
the art that the foregoing and other changes in form and detail may be
made therein without departing from the spirit and scope of the invention.
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